Specific degradation of 3′ regions of GUS mRNA in posttranscriptionally silenced tobacco lines may be related to 5′-3′ spreading of silencing

THOMAS HARTIG BRAUNSTEIN; BENOIT MOURY; MARINA JOHANNESSEN; MERETE ALBRECHTSEN

doi:10.1017/S1355838202026080

Abstract

Target regions for posttranscriptional silencing of transgenes often reside in the 3′ region of the coding sequence, although there are exceptions. To resolve if the target region is determined by the gene undergoing silencing rather than by the structure of the transgene loci or the plant genetic background, we have performed detailed analyses of target regions in three spontaneously β-glucuronidase (GUS) silencing tobacco lines of different origin. From quantitative cosuppression experiments, we show that the main target region in all three tobacco lines is found within the 3′ half of the GUS coding region but upstream of the last 200 nt. The quantities of small (21–25 nt) RNAs homologous to 5′ or 3′ regions of the GUS coding sequence were found to correlate approximately with the target strength of the corresponding regions. These results suggest that transgene locus structure and plant genetic background are not major determinants of silencing target regions. We also show that virus-induced gene silencing (VIGS) of GUS in Nicotiana benthamiana is induced equally effectively with Potato virus X carrying either the 5′ or 3′ third of the GUS coding region. This indicates that both regions can act as efficient inducers as well as targets of posttranscriptional silencing, although the 3′ region is the predominant target region in the spontaneously silencing transgenic plant lines examined. Finally, we investigated spreading of the target region in the N. benthamiana plants undergoing VIGS. Surprisingly, only evidence for spreading of the target region in the 5′-3′ direction was obtained. This finding may help explain why the majority of target regions examined to date lie within the 3′ region of transgenes.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Van Houdt, Helena Bleys, Annick and Depicker, Anna 2003. RNA Target Sequences Promote Spreading of RNA Silencing. Plant Physiology, Vol. 131, Issue. 1, p. 245.

García‐Pérez, Rubén Darío Houdt, Helena Van and Depicker, Anna 2004. Spreading of post‐transcriptional gene silencing along the target gene promotes systemic silencing. The Plant Journal, Vol. 38, Issue. 4, p. 594.

Petersen, Birgit Otzen Jørgensen, Bodil and Albrechtsen, Merete 2004. Isolation and RNA silencing of homologues of the RNase L inhibitor in Nicotiana species. Plant Science, Vol. 167, Issue. 6, p. 1283.

Vogt, Ulrike Pélissier, Thierry Pütz, Arno Razvi, Fareha Fischer, Rainer and Wassenegger, Michael 2004. Viroid‐induced RNA silencing of GFP‐viroid fusion transgenes does not induce extensive spreading of methylation or transitive silencing. The Plant Journal, Vol. 38, Issue. 1, p. 107.

Tang, Wei Samuels, Vanessa Whitley, Nicki Bloom, Nicole DeLaGarza, Tinya and Newton, Ronald J. 2004. Post-transcriptional Gene Silencing Induced by Short Interfering RNAs in Cultured Transgenic Plant Cells. Genomics, Proteomics & Bioinformatics, Vol. 2, Issue. 2, p. 97.

Miki, Daisuke Itoh, Rika and Shimamoto, Ko 2005. RNA Silencing of Single and Multiple Members in a Gene Family of Rice. Plant Physiology, Vol. 138, Issue. 4, p. 1903.

Petersen, Birgit Otzen and Albrechtsen, Merete 2005. Evidence implying only unprimed RdRP activity during transitive gene silencing in plants. Plant Molecular Biology, Vol. 58, Issue. 4, p. 575.

Kościańska, Edyta Kalantidis, Kriton Wypijewski, Krzysztof Sadowski, Jan and Tabler, Martin 2005. Analysis of RNA Silencing in Agroinfiltrated Leaves of Nicotiana Benthamiana and Nicotiana Tabacum. Plant Molecular Biology, Vol. 59, Issue. 4, p. 647.

GRANT-DOWNTON, R. T. and DICKINSON, H. G. 2005. Epigenetics and its Implications for Plant Biology. 1. The Epigenetic Network in Plants. Annals of Botany, Vol. 96, Issue. 7, p. 1143.

Bleys, Annick Van Houdt, Helena and Depicker, Anna 2006. Down-regulation of endogenes mediated by a transitive silencing signal. RNA, Vol. 12, Issue. 9, p. 1633.

Bleys, Annick Vermeersch, Leen Van Houdt, Helena and Depicker, Anna 2006. The Frequency and Efficiency of Endogene Suppression by Transitive Silencing Signals Is Influenced by the Length of Sequence Homology. Plant Physiology, Vol. 142, Issue. 2, p. 788.

Heilersig, H. J. B. Loonen, A. Bergervoet, M. Wolters, A. M. A. and Visser, R. G. F. 2006. Post-transcriptional Gene Silencing of GBSSI in Potato: Effects of Size and Sequence of the Inverted Repeats. Plant Molecular Biology, Vol. 60, Issue. 5, p. 647.

Haque, A. K. M. N. Tanaka, Yoshikazu Sonoda, Shoji and Nishiguchi, Masamichi 2006. Analysis of transitive RNA silencing after grafting in transgenic plants with the coat protein gene of Sweet potato feathery mottle virus. Plant Molecular Biology, Vol. 63, Issue. 1, p. 35.

Filichkin, Sergei A. DiFazio, Stephen P. Brunner, Amy M. Davis, John M. Yang, Zamin K. Kalluri, Udaya C. Arias, Renee S. Etherington, Elizabeth Tuskan, Gerald A. and Strauss, Steven H. 2007. Efficiency of gene silencing in Arabidopsis: direct inverted repeats vs. transitive RNAi vectors. Plant Biotechnology Journal, Vol. 5, Issue. 5, p. 615.

Shimamura, Katsuyoshi Oka, Shin-ichiro Shimotori, Yumi Ohmori, Takashi and Kodama, Hiroaki 2007. Generation of secondary small interfering RNA in cell-autonomous and non-cell autonomous RNA silencing in tobacco. Plant Molecular Biology, Vol. 63, Issue. 6, p. 803.

Zhou, Y. Ryabov, E. Zhang, X. and Hong, Y. 2008. Influence of viral genes on the cell-to-cell spread of RNA silencing. Journal of Experimental Botany, Vol. 59, Issue. 10, p. 2803.

Kemppainen, Minna J. and Pardo, Alejandro G. 2010. pHg/pSILBAγ vector system for efficient gene silencing in homobasidiomycetes: optimization of ihpRNA – triggering in the mycorrhizal fungus Laccaria bicolor. Microbial Biotechnology, Vol. 3, Issue. 2, p. 178.

Sun, Zhao‐Nan Song, Yun‐Zhi Yin, Guo‐Hua Zhu, Chang‐Xiang and Wen, Fu‐Jiang 2010. HpRNAs Derived from Different Regions of the NIb Gene Have Different Abilities to Protect Tobacco from Infection with Potato Virus Y. Journal of Phytopathology, Vol. 158, Issue. 7-8, p. 566.

Wagner, Nicholas Mroczka, Andrew Roberts, Peter D. Schreckengost, William and Voelker, Toni 2011. RNAi trigger fragment truncation attenuates soybean FAD2‐1 transcript suppression and yields intermediate oil phenotypes. Plant Biotechnology Journal, Vol. 9, Issue. 7, p. 723.

Zhang, C. Song, Y. Jiang, F. Li, G. Jiang, Y. Zhu, C. and Wen, F. 2012. Virus resistance obtained in transgenic tobacco and rice by RNA interference using promoters with distinct activity. Biologia plantarum, Vol. 56, Issue. 4, p. 742.

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Specific degradation of 3′ regions of GUS mRNA in posttranscriptionally silenced tobacco lines may be related to 5′-3′ spreading of silencing

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Specific degradation of 3′ regions of GUS mRNA in posttranscriptionally silenced tobacco lines may be related to 5′-3′ spreading of silencing

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